با همکاری انجمن علوم و صنایع غذایی ایران

نوع مقاله : مقاله پژوهشی

نویسندگان

1 ، گروه پژوهشی افزودنی‌های غذایی، پژوهشکده علوم و فناوری مواد غذایی، سازمان جهاد دانشگاهی خراسان رضوی

2 گروه علوم و صنایع غذایی، موسسه آموزش عالی جهاد دانشگاهی کاشمر، کاشمر، ایران.

چکیده

آنتوسیانین‌ها یکی از مهمترین رنگدانه‎های غذایی هستند که کاربرد گسترده‎ای در محصولات غذایی دارند. یکی از منابع مستعد آنتوسیانین در ایران، گلبرگ زعفران می‎باشد. پایداری حرارتی نسبتا پایین آنتوسیانین‎ها موجب استفاده بیشتر از رنگ‎های سنتزی شده است.  هدف این پژوهش، بررسی تاثیر سیکلودکسترین‌ها و کوپیگمانتاسیون بر پایداری عصاره آنتوسیانینی استخراجی از گلبرگ زعفران در برابر تیمار حرارتی بود. از غلظت‎های مختلف آلفا و بتاسیکلودکسترین (10، 25، 50، 75 و 100 مول آلفا/ بتاسیکلودکسترین به ازای 1 مول آنتوسیانین) و همچنین از کوپیگمان‎های مختلفی ازقبیل گالیک اسید (در دو نسبت مولی 50 به 1 و 100 به 1 نسبت به آنتوسیانین)، فرولیک اسید (در دو نسبت مولی 50 به 1 و 100 به 1 نسبت به آنتوسیانین)، کوئرستین (در دو نسبت مولی 5/2 به 1 و 5 به 1 نسبت به آنتوسیانین) و روتین (در دو نسبت مولی 10 به 1 و 25 به 1 نسبت به آنتوسیانین) و عصاره نسترن کوهی (در دو نسبت مولی 50 به 1 و 100 به 1 معادل گالیک اسید به آنتوسیانین) برای بررسی پایداری حرارتی آنتوسیانین‎ها استفاده شد. نتایج حاکی از آن بود که آلفاسیکلودکسترین تاثیر معنی‎داری در سطح اطمینان 95 درصد (05/0 p<) بر پایداری آنتوسیانین نداشت اما بتاسیکلودکسترین در نسبت مولی 50 به 1 (بتاسیکلودکسترین به آنتوسیانین) موجب افزایش پایداری رنگدانه شد. اگرچه ترکیبات فنولی تاثیری در پایدارسازی حرارتی آنتوسیانین‎های نوشیدنی مدل نداشتند اما عصاره نسترن کوهی در هر دو نسبت مولی 50 و 100 به 1 موجب افزایش معنی‎دار بقاء آنتوسیانین‎ها شد. بنابراین، بتاسیکلودکسترین به‌عنوان یک ترکیب پوشاننده و عصاره نسترن کوهی به‌عنوان یک ترکیب کوپیگمان می‎توانند موجب افزایش پایداری آنتوسیانین گلبرگ زعفران طی تیمار حرارتی شوند.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Effect of cyclodextrins and co-pigmentation on the thermal stability of the anthocyanin extract of Saffron petal in the model drink

نویسندگان [English]

  • Hamed Saberian 1
  • Vahid Pasban 2

1 Food Additives Department, Food Science and Technology Research Institute, ACECR, Khorasan Razavi, Iran.

2 Department of Food Science and Technology, ACECR Kashmar Higher Education Institute, Kashmar, Iran.

چکیده [English]

[1]Introduction: Anthocyanins are one of the most important of food colorants, which are found in many fruits, flowers, and vegetables, and have been used as natural pigments in commercial foods and beverage products due to their desirable colors and potential nutritional benefits. Saffron (Crocus sativus) is the most expensive spice of the world and an average 86.4% of wet weight or 96.4% of dry weight of saffron flowers is related to petals. Saffron petals usually do not have a commercial value but contain large amounts of anthocyanins, flavonoids and glycosides. Thus, these petals can be a good source of natural dyes applicable in pharmaceuticals, confectionery, and soft drinks. However, anthocyanins are readily unstable compounds with exposure to oxygen, pH, temperature, enzyme, light, as well as surrounding components, which reduces food color and quality. Losses of anthocyanins occur during juice processing and storage, and methods are needed to prevent these losses. Up to now, various methods including the encapsulation and the co-pigmentation have been tried to intensify the stability of anthocyanins. The co-pigmentation based on the molecular interactions, has been shown to be an efficient way to stabilize anthocyanins. The addition of organic acids, flavonoids, alkaloids, polysaccharides, proteins, etc. as a co-pigment, can improve the stability, and change the bioactivity of anthocyanins. Encapsulation of anthocyanins by alpha and beta cyclodextrins is a potential treatment that could d anthocyanin losses. Anthocyanins can form inclusion complexes with cyclodextrin molecules, which may protect anthocyanins from hydration and polymerization reactions. Therefore, saffron petal is a potential resource of anthocyanin in Iran. Low thermal stability of the anthocyanins caused a tendency to the synthetic colorants. Therefore, the main goal of this research was to investigate the effect of cyclodextrins and co-pigmentation on the anthocyanin extract of saffron petal during heat treatment.
 
Materials and Methods: Anthocyanin extract of saffron petal was extracted by 50% acidic ethanol solution at ambient temperature. Acidified extract was concentrated by a rotary evaporator at 40˚C up to 9 percent concentration of solid materials. Different concentrations of alpha and beta cyclodextrin (10, 25, 50, 75 and 100 mole alpha or beta cyclodextrin to one mole anthocyanin) and also, different co-pigments such as gallic acid (at two molar ratio of 50:1 and 100:1of galic acid/anthocyanin), ferulic acid (at two molar ratio of 50:1 and 100:1of ferulic acid/anthocyanin), quercetin (at two molar ratio of 2.5:1 and 5:1 of quercetin/anthocyanin) and rutin (at two molar ratio of 10:1 and 25:1 of rutin/anthocyanin) were used to study the thermal stability of anthocyanin. Furthermore, the hydroalcoholic extract of rosehip was prepared and concentrated thereby, the rosehip extract (at two molar ratio of 50:1 and 100:1gallic acid equivalent/anthocyanin) was used as a co-pigment. Total anthocyanin content was measured using differential pH method and reported based on mg of cyanidin 3-glucoside per 100 ml the model drink. a* value was measured by Hunter Lab. Model drink (20 mM acid citric buffer in pH of 3) containing 0.01 % CaCl2 and anthocyanin extract was prepared. Prepared model drinks were heated at 90 °C during 0, 15, 30, 45, 60, 90 and 120 min and then, were cooled up to room temperature. Half time of anthocyanin was calculated and the mentioned treatments were investigated to evaluate the stability of the different compounds.
 
Results and Discussion: The results indicated that alpha cyclodextrin at molar ratio of 50:1 (alpha cyclodextrin to anthocyanin) hadn’t any significant effect on the anthocyanin stability but beta cyclodextrin at molar ratio of 50:1 increased the colorant stability, which can be due to the smaller cavity of alpha cyclodextrin rather than beta cyclodextrin that lead to the lower interaction between alpha cyclodextrin and anthocyanin. Although, phenolic co-pigments hadn’t any significant effect on the anthocyanin stability of the model drink but the rosehip extract at two molar ratios of 50:1 and 100: 1 increased the anthocyanin retention. Total phenolic content of rosehip extract was 14.56 g gallic acid equivalent per liter of the extract and total flavonoid content was 365 mg quercetin equivalent per liter of the extract. According to the studies and our results about total phenol and flavonoid content, the increased retention of the anthocyanin can be related to the variety of the phenolic and flavonoid compounds of the rosehip extract. Therefore, beta cyclodextrin as a trapping agent and rosehip extract as a co-pigment, can increase the anthocyanin stability of the saffron petal during heat treatment.
 

کلیدواژه‌ها [English]

  • Thermal stabilization
  • Anthocyanin
  • saffron petal
  • β-cyclodextrin
  • Rosehip extract
  1. Asen, S., Stewart, R. N., & Norris, K. H. (1972). Co-pigmentation of anthocyanins in plant tissues and its effect on color. Phytochemistry, 11(3), 1139-1144. https://doi.org/10.1016/S0031-9422(00)88467-8
  2. Bolourian, Sh. (2020). Optimization of the extraction the anthocyanin extract of the saffron petal. Research project, ACECR, Research institute of the Food Science and technology. [In Persian]
  3. Bourvellec, C. (2003). Association entre les procyanidols et les polymères pariétaux de pommes: quantification et conséquences(Doctoral dissertation, Rennes 1).
  4. Carocho, M., Barreiro, M.F., Morales, P. & Ferreira, I.C. (2014). Adding molecules to food, pros and cons: A review on synthetic and natural food additives. Comprehensive Review of Food Science and Food Safety, 13, 377–99. https://doi.org/10.1111/1541-4337.12065
  5. Cavalcanti, R.N., Santos, D.T. & Meireles, M.A.A. (2011). Non-thermal stabilization mechanisms of anthocyanins in model and food systems: an overview. Food Research International, 44, 499–509. https://doi.org/10.1016/j.foodres.2010.12.007
  6. ‎Chang, C.C., Yang, M.H., Wen, H.M., & Chern, J.C. (2002). Estimation of total flavonoid content in propolis ‎by two complementary colorimetric methods. Journal of food drug analysis, 10(3), 178-182.
  7. Chung, C., Rojanasasithara, T., Mutilangi, W. & McClements, D.J. (2015). Enhanced stability of anthocyanins based color in model beverage systems through whey protein isolate complexation. Food Chemistry, 76, 761–8. https://doi.org/10.1016/j.foodres.2015.07.003
  8. Chung, C., Rojanasasithara, T., Mutilangi, W., & McClements, D. J. (2016). Enhancement of colour stability of anthocyanins in model beverages by gum arabic addition. Food Chemistry201, 14-22. https://doi.org/10.1016/j.foodchem.2016.01.051
  9. Cortez, R., Luna‐Vital, D. A., Margulis, D., & Gonzalez de Mejia, E. (2017). Natural pigments: stabilization methods of anthocyanins for food applications. Comprehensive Review of Food Science and Food Safety, 16(1), 180-198. https://doi.org/10.1111/1541-4337.12244
  10. Einafshar, S. (2018) the production of the colorants and natural antioxidant from the saffron petal waste, Journal of Saffron, 1(1), 25-33. [In Persian]
  11. Ercisli, S. (2007). Chemical composition of fruits in some rose (Rosa spp.) species. Food Chemistry, 104(4), 1379-‎‎ ‎ https://doi.org/10.1016/j.foodchem.2007.01.053
  12. Ertan, K., Türkyılmaz, M., & Özkan, M. (2018). Effect of sweeteners on anthocyanin stability and colour properties of sour cherry and strawberry nectars during storage. Journal of food Science and Technology55(10), 4346-4355. https://doi.org/10.1007/s13197-018-3387-4
  13. Fan, L., Wang, Y., Xie, P., Zhang, L., Li, Y., & Zhou, J. (2019). Copigmentation effects of phenolics on color enhancement and stability of blackberry wine residue anthocyanins: Chromaticity, kinetics and structural simulation. Food chemistry,275, 299-308. https://doi.org/10.1016/j.foodchem.2018.09.103
  14. Fernandes, A., Azevedo, J., Mateus, N. & Freitas, V.D. (2013). Effect of cyclodextrins on the thermodynamic and kinetic properties of cyanidin-3-O-glucoside. Food Research International, 51(2), 748–55. https://doi.org/10.1016/j.foodres.2013.01.037
  15. Ge, J., Yue, P., Chi, J., Liang, J., & Gao, X. (2018). Formation and stability of anthocyanins-loaded nanocomplexes prepared with chitosan hydrochloride and carboxymethyl chitosan. Food Hydrocolloids74, 23-31. https://doi.org/10.1016/j.foodhyd.2017.07.029
  16. Howard, L.R, Brownmiller, C., Prior, R.L. & Mauromoustakos, A. (2013). Improved stability of chokeberry juice anthocyanins by β-cyclodextrin addition and refrigeration. Journal of Agriculture of Food Chemistry, 61(3), 693–9. https://doi.org/10.1021/jf3038314
  17. Jafari, S. M., Mahdavi-Khazaei, K., & Hemmati-Kakhki, A. (2016). Microencapsulation of saffron petal anthocyanins with cress seed gum compared with Arabic gum through freeze drying. Carbohydrate Polymer,140, 20-25. https://doi.org/10.1016/j.carbpol.2015.11.079
  18. Kanha, N., Surawang, S., Pitchakarn, P., Regenstein, J. M., & Laokuldilok, T. (2019). Copigmentation of cyanidin 3-O-glucoside with phenolics: Thermodynamic data and thermal stability. Food Bioscience30, 100-419. https://doi.org/10.1016/j.fbio.2019.100419
  19. Khazaei, K.M., Jafari, S.M., Ghorbani, M. & Hemmati Khakki, A. (2014). Application of maltodextrin and gum Arabic in microencapsulation of saffron petal’s anthcyanins and evaluating their stability. Carbohydrate Polymer, 105, 57-62. https://doi.org/10.1016/j.carbpol.2014.01.042
  20. Kopjar, M., Bilić, B., & Piližota, V. (2014). Anthocyanins, phenols, and antioxidant activity in blackberry juice with plant extracts addition during heating. Acta alimentaria43(2), 333-343.
  21. Li, X., Xu, J., Tang, X., Liu, Y., Yu, X., Wang, Z. & Liu, W. (2016). Anthocyanins inhibit trastuzumab resistant breast cancer in vitro and in vivo. Molecular Medicine Report, 13, 4007–4013.
  22. Mazza, G. & Miniati, E. (1993). Anthocyanins in fruits, vegetables, and grains. Boca Raton: CRC Press.
  23. Mollov, P., Mihalev, K., Shikov, V., Yoncheva, N., & Karagyozov, V. (2007). Colour stability improvement of strawberry beverage by fortification with polyphenolic copigments naturally occurring in rose petals. Innovative Food Science Emerging Technology,8(3), 318-321. https://doi.org/10.1016/j.ifset.2007.03.004
  24. Saberian, H. (2018). The comparison of the quality properties of the rosehip powder of some regions of Iran with commercial sample, Journal of food Science and Technology, 15 (82), 139-149. [In Persian]
  25. Saberian, H. (2020). Production of food supplement of rosehip as a capsule to treat arthritis, ACECR, Research institute of the Food Science and technology. [In Persian]
  26. Saberian, H., Hamidi-Esfahani, Z., & Abbasi, S. (2013). Effect of pasteurization and storage on bioactive components of Aloe vera gel. Nutrition & Food Science, 43(2), 175-183.
  27. Shikov, V., Kammerer, D. R., Mihalev, K., Mollov, P., & Carle, R. (2008). Heat stability of strawberry anthocyanins in model solutions containing natural copigments extracted from rose (Rosa damascena) petals. Journal of agriculture food Chemistry56(18), 8521-8526. https://doi.org/10.1021/jf801946g
  28. Sui, X., Dong, X. & Zhou, W. (2014). Combined effect of pH and high temperature on the stability and antioxidant capacity of 2 anthocyanins in aqueous solution. Food Chemistry, 163, 163–70. https://doi.org/10.1016/j.foodchem.2014.04.075
  29. Weber, F., Boch, K., & Schieber, A. (2017). Influence of copigmentation on the stability of spray dried anthocyanins from blackberry. LWT-Food Science and Technology, 75, 72-77. https://doi.org/10.1016/j.lwt.2016.08.042
  30. Zhao, X., Ding, B. W., Qin, J. W., He, F., & Duan, C. Q. (2020). Intermolecular copigmentation between five common 3-O-monoglucosidic anthocyanins and three phenolics in red wine model solutions: The influence of substituent pattern of anthocyanin B ring. Food chemistry326, 126960. https://doi.org/10.1016/j.foodchem.2020.126960

 

CAPTCHA Image